V(D)J recombinase-mediated processing of coding junctions at cryptic recombination signal sequences in peripheral T cells during human development

V(D)J recombinase mediates rearrangements at immune loci and cryptic recombination signal sequences (cRSS), resulting in a variety of genomic rearrangements in normal lymphocytes and leukemic cells from children and adults. The frequency at which these rearrangements occur and their potential pathologic consequences are developmentally dependent. To gain insight into V(D)J recombinase-mediated events during human development, we investigated 265 coding junctions associated with cRSS sites at the hypoxanthine-guanine phosphoribosyltransferase (HPRT) locus in peripheral T cells from 111 children during the late stages of fetal development through early adolescence. We observed a number of specific V(D)J recombinase processing features that were both age and gender dependent. In particular, TdT-mediated nucleotide insertions varied depending on age and gender, including percentage of coding junctions containing N-nucleotide inserts, predominance of GC nucleotides, and presence of inverted repeats (Pr-nucleotides) at processed coding ends. In addition, the extent of exonucleolytic processing of coding ends was inversely related to age. We also observed a coding-partner-dependent difference in exonucleolytic processing and an age-specific difference in the subtypes of V(D)J-mediated events. We investigated these age- and gender-specific differences with recombination signal information content analysis of the cRSS sites in the human HPRT locus to gain insight into the mechanisms mediating these developmentally specific V(D)J recombinase-mediated rearrangements in humans.     

In vivo transposition mediated by V(D)J recombinase in human T lymphocytes

The rearrangement of immunoglobulin (Ig) and T-cell receptor (TCR) genes in lymphocytes by V(D)J recombinase is essential for immunological diversity in humans. These DNA rearrangements involve cleavage by the RAG1 and RAG2 (RAG1/2) recombinase enzymes at recombination signal sequences (RSS). This reaction generates two products, cleaved signal ends and coding ends. Coding ends are ligated by non-homologous end-joining proteins to form a functional Ig or TCR gene product, while the signal ends form a signal joint. In vitro studies have demonstrated that RAG1/2 are capable of mediating the transposition of cleaved signal ends into non-specific sites of a target DNA molecule. However, to date, in vivo transposition of signal ends has not been demonstrated. We present evidence of in vivo inter-chromosomal transposition in humans mediated by V(D)J recombinase. T-cell isolates were shown to contain TCRalpha signal ends from chromosome 14 inserted into the X-linked hypo xanthine-guanine phosphoribosyl transferase locus, resulting in gene inactivation. These findings implicate V(D)J recombinase-mediated transposition as a mutagenic mechanism capable of deleterious genetic rearrangements in humans.     

Assessing the pathogenic potential of the V(D)J recombinase by interlocus immunoglobulin light-chain gene rearrangement.

Chromosomal translocations involving antigen receptor genes and oncogenes have been observed in several forms of lymphoid malignancy. Observations of their lymphocyte-restricted occurrence and a molecular analysis of some translocation breakpoints have suggested that some of these rearrangements are generated by V(D)J recombinase activity. However, a direct correlation between this activity and the generation of such rearrangements has never been established. In addition, because these aberrant rearrangements are usually detected only after a tumor has been formed, the frequency with which the recombinase machinery generates translocations has never been assessed directly. To approach these issues, immunoglobulin light-chain gene rearrangements were induced in pre-B cells transformed by temperature-sensitive mutants of Abelson murine leukemia virus and PCR was used to identify interlocus recombinants. Vlambda Jkappa and Vkappa Jlambda rearrangements as well as signal joints resulting from the recombination of Vlambda and Jkappa coding elements were recovered and were found to be similar in structure to conventional intrachromosomal joints. Because these products were detected only when the cells were undergoing active intralocus rearrangement, they provide direct evidence that translocations can be generated by the V(D)J recombinase machinery. Dilution analyses revealed that interlocus rearrangements occur about 1,000 times less frequently than conventional intralocus rearrangements. Considering the large numbers of lymphocytes generated throughout life, aberrant rearrangements generated by the V(D)J recombinase may be relatively common.     

Abnormal deletions in the T-cell receptor delta locus of mouse thymocytes.

Separate genetic elements (V, D, and J) encode the variable regions of lymphocyte antigen receptors. During early lymphocyte differentiation, these elements rearrange to form contiguous coding segments (VJ and VDJ) for a diverse array of variable regions. Rearrangement is mediated by a recombinase that recognizes short DNA sequences (signals) flanking V, D, and J elements. Signals flank both the 5' and 3' sides of each D element, thereby allowing assembly of a functional VDJ gene. However, in rearrangements involving the D delta 2 and J delta 1 elements of the mouse T-cell receptor delta (TCR delta) locus, we unexpectedly found that the D delta 2 element and a portion of its 5' signal are often deleted. Approximately 50% of recovered D delta 2 to J delta 1 rearrangements from thymocytes of adult wild-type mice showed such deletions. An additional 20% of the rearrangements contained standard D delta 2-J delta 1 coding junctions but showed some loss of nucleotides from the 5' D delta 2 signal. This loss was clearly associated with another event involving a site-specific cleavage at the 5' signal/coding border of D delta 2 and rejoining of the modified signal and coding ends. The abnormal loss of D delta 2 and a portion of the 5' D delta 2 signal was infrequently observed in D delta 2-to-J delta 1 rearrangements recovered from neonatal mice. The possible basis and significance of this age-dependent phenomenon are discussed.     

V(D)J recombinase-mediated deletion of the hprt gene in T-lymphocytes from adult humans.

The hprt T-cell cloning assay allows the detection of mutations occurring in vivo in the hypoxanthine-guanine phosphoribosyltransferase (hprt) gene of T-lymphocytes. We have shown previously that the illegitimate activity of V(D)J recombinase accounts for about 40% of the hprt mutations in T-lymphocytes of human newborns as measured with umbilical cord blood samples (Fuscoe et al., 1991). This mechanism results in deletion of hprt exons 2 + 3. In this report, we examined a collection of 314 HPRT-deficient clones derived from adult humans for evidence that the mutations were caused by this mechanism by analyzing exons 2 + 3 deletion mutations. DNA sequence analysis of deletion breakpoint junctions showed that 8 of the mutations were the result of V(D)J recombinase activity. The frequency of the recombinase-mediated mutations was similar in the adults and newborns (2-4 x 10(-7). However, since the hprt mutant frequency is about 10-fold higher in the adult than in the newborn, the recombinase-mediated mutations account for only a few percent of the adult mutations. These mutations are likely to have occurred during early development and persist into adulthood. Unregulated expression of V(D)J recombinase activity may be an important mechanism for genomic rearrangements in the genesis of cancer.     

Autoantibody-encoding kappa L chain genes frequently rearranged in lambda L chain-expressing chronic lymphocytic leukemia

Patients with kappa L chain expressing chronic lymphocytic leukemia (CLL) frequently have leukemia cells reactive with a murine mAb, designated 17.109. Raised against a monoclonal IgM rheumatoid factor autoantibody, this mAb recognizes a major kappa-L chain-associated cross reactive Id, designated 17.109-CRI. Molecular studies reveal that the 17.109-CRI in CLL is a serologic marker for expression of a conserved kappa L chain V region gene (V Kappa gene) of the V Kappa 3 subgroup, designated Humkv325. We isolated an upstream gene fragment of Humkv325 to examine for Ig gene rearrangements of this and other closely related V Kappa 3 genes by Southern analyses. Consistent with Humkv325 encoding the 17.109-CRI, we find that the genomic DNA from all 17.109-reactive leukemia cell populations have gene rearrangements that are detected using this probe. In addition, we observe V Kappa 3 gene rearrangements frequently in the genomic DNA of lambda L chain-expressing leukemia cells. Of the genomic DNA from 33 lambda-L chain-expressing CLL samples, 8 (24%) had additional nongerm-line bands detected with the Humkv325 probe. Consistent with these bands representing Ig gene rearrangements, the additional band in each but one sample also hybridized with probes specific for the J Kappa region and/or the kappa-deleting element. Using the polymerase chain reaction (PCR), we examined the genomic DNA from all lambda L chain-expressing CLL for V Kappa 3 gene rearrangements to J Kappa and/or Kde. PCR on each DNA sample with V Kappa 3 gene rearrangements detected by Southern analysis generated gene fragments that hybridized specifically with oligonucleotides corresponding to framework or CDR of the Humkv325 gene. Nucleic acid sequence analyses of representative samples confirmed that these DNA contained abortive Humkv325 gene rearrangements. PCR for rearranged V Kappa 3 genes in the DNA of other lambda-L chain-expressing CLL either did not generate any PCR product or produced fragments that failed to hybridize with all Humkv325 oligonucleotide probes. Nucleic acid sequence analyses of the latter demonstrated that these represent abortive V Kappa gene rearrangements involving another conserved V Kappa 3 gene, designated Vg. These studies indicate that Humkv325 and Vg frequently may undergo Ig gene rearrangement independent of their expression. As such, the frequent use of Humkv325 in CLL may be secondary, in part, to an enhanced propensity of this V Kappa 3 gene to undergo genetic rearrangement during B cell ontogeny.     

Antigenic stimulation induces recombination activating gene 1 and terminal deoxynucleotidyl transferase expression in a murine T-cell hybridoma

Secondary rearrangements of the T cell receptor (TCR) represent a genetic correction mechanism which changes T cell specificity by re-activating V(D)J recombination in peripheral T cells. Murine T-cell hybridoma A1.1 was employed to investigate whether antigenic stimulation induced re-expression of recombinase genes and altered TCR Vβ expression. Following repeated antigenic stimulation, A1.1 cells were induced to re-express recombination activating gene (RAG)1 and terminal deoxynucleotidyl transferase (TdT) which are generally considered prerequisite to TCR gene rearrangement. Accompanied with the significant changes in TCR mRNA levels over time, it is suggested that secondary rearrangements may be induced in A1.1 cells, which represent a mature T cell clone capable of re-expressing RAG genes and possesses the prerequisite for secondary V(D)J rearrangement.     

The V(D)J recombination activating gene, RAG-1

The RAG-1 (recombination activating gene-1) genomic locus, which activates V(D)J recombination when introduced into NIH 3T3 fibroblasts, was isolated by serial genomic transfections of oligonucleotide-tagged DNA. A genomic walk spanning 55 kb yielded a RAG-1 genomic probe that detects a single 6.6-7.0 kb mRNA species in transfectants and pre-B and pre-T cells. RAG-1 genomic and cDNA clones were biologically active when introduced into NIH 3T3 cells. Nucleotide sequencing of human and mouse RAG-1 cDNA clones predicts 119 kd proteins of 1043 and 1040 amino acids, respectively, with 90% sequence identity. RAG-1 has been conserved between species that carry out V(D)J recombination, and its pattern of expression correlates exactly with the pattern of expression of V(D)J recombinase activity. RAG-1 may activate V(D)J recombination indirectly, or it may encode the V(D)J recombinase itself.     

The NF-kappaB canonical pathway is involved in the control of the exonucleolytic processing of coding ends during V(D)J recombination

V(D)J recombination is essential to produce an Ig repertoire with a large range of Ag specificities. Although NF-kappaB-binding sites are present in the human and mouse IgH, Igkappa, and Iglambda enhancer modules and RAG expression is controlled by NF-kappaB, it is not known whether NF-kappaB regulates V(D)J recombination mechanisms after RAG-mediated dsDNA breaks. To clarify the involvement of NF-kappaB in human V(D)J recombination, we amplified Ig gene rearrangements from individual peripheral B cells of patients with X-linked anhidrotic ectodermal dysplasia with hyper-IgM syndrome (HED-ID) who have deficient expression of the NF-kappaB essential modulator (NEMO/Ikkgamma). The amplification of nonproductive Ig gene rearrangements from HED-ID B cells reflects the influence of the Ikkgamma-mediated canonical NF-kappaB pathway on specific molecular mechanisms involved in V(D)J recombination. We found that the CDR3(H) from HED-ID B cells were abnormally long, as a result of a marked reduction in the exonuclease activity on the V, D, and J germline coding ends, whereas random N-nucleotide addition and palindromic overhangs (P nucleotides) were comparable to controls. This suggests that an intact canonical NF-kappaB pathway is essential for normal exonucleolytic activity during human V(D)J recombination, whereas terminal deoxynucleotide transferase, Artemis, and DNA-dependent protein kinase catalytic subunit activity are not affected. The generation of memory B cells and somatic hypermutation were markedly deficient confirming a role for NF-kappaB in these events of B cell maturation. However, selection of the primary B cell repertoire appeared to be intact and was partially able to correct the defects generated by abnormal V(D)J recombination.     

Full-length RAG-2, and not full-length RAG-1, specifically suppresses RAG-mediated transposition but not hybrid joint formation or disintegration

RAG-1 and RAG-2 initiate V(D)J recombination by introducing DNA breaks at recombination signal sequences flanking a pair of antigen receptor gene segments. Occasionally, the RAG proteins mediate two other alternative DNA rearrangements in vivo: the rejoining of signal and coding ends and the transposition of signal ends into unrelated DNA. In contrast, truncated, catalytically active "core" RAG proteins readily catalyze these reactions in vitro, suggesting that full-length RAG proteins directly or indirectly suppress these undesired reactions in vivo. To discriminate between direct and indirect suppression models, full-length RAG proteins were purified and characterized in vitro. From mammalian cells, full-length RAG-1 is readily purified with core RAG-2 but not full-length RAG-2 and vice versa. Despite differences in DNA binding activity, recombinase containing either core or full-length RAG-1 or RAG-2 possess comparable cleavage, rejoining, and end-processing activity, as well as similar usage preferences for canonical versus cryptic recombination signals. However, recombinase containing full-length RAG-2, but not full-length RAG-1, exhibits dramatically reduced transposition activity in vitro. These data suggest RAG-mediated transposition and rejoining are differentially regulated by the full-length RAG proteins in vivo (the former directly by RAG-2 and the latter indirectly through other factors) and argue that noncore portions of the RAG proteins have little or no direct influence over V(D)J recombinase site specificity.     

Strand breaks without DNA rearrangement in V (D)J recombination.

Somatic gene rearrangement of immunoglobulin and T-cell receptor genes [V(D)J recombination] is mediated by pairs of specific DNA sequence motifs termed signal sequences. In experiments described here, retroviral vectors containing V(D)J rearrangement cassettes in which the signal sequences had been altered were introduced into wild-type and scid (severe combined immune deficiency) pre-B cells and used to define intermediates in the V(D)J recombination pathway. The scid mutation has previously been shown to deleteriously affect the V(D)J recombination process. Cassettes containing a point mutation in one of the two signal sequences inhibited rearrangement in wild-type cells. In contrast, scid cells continued to rearrange these cassettes with the characteristic scid deletional phenotype. Using these mutated templates, we identified junctional modifications at the wild-type signal sequences that had arisen from strand breaks which were not associated with overall V(D)J rearrangements. Neither cell type was able to rearrange constructs which contained only a single, nonmutated, signal sequence. In addition, scid and wild-type cell lines harboring cassettes with mutations in both signal sequences did not undergo rearrangement, suggesting that at least one functional signal sequence was required for all types of V(D)J recombination events. Analysis of these signal sequence mutations has provided insights into intermediates in the V(D)J rearrangement pathway in wild-type and scid pre-B cells.     

Nuclear matrix bound V(D)J recombination activity in rat thymus nuclei: an in vitro system

We report here that a high level of V(D)J recombination activity is tightly associated with high-salt-resistant nuclear matrix isolated from thymus glands from 2- to 3-week-old rats. The soluble nuclear fractions either were devoid of or contained a very low level of recombinase activity. This is the first time that the process mimicking V(D)J recombination has been achieved in an in vitro system. The matrix-bound V(D)J recombinase activity was further found to be lymphoid specific, detectable only during early stages of development. These observations suggest that in vitro recombination of V(D)J segments of genes encoding antigen-binding proteins could be a matrix-bound process and that the nuclear matrix may be an important intranuclear domain for the functional organization of the V(D)J recombinase system.     

Immunoglobulin gene rearrangements in normal mouse B cells.

We have analyzed the structure of rearranged mu heavy-chain genes obtained from the genomic DNA of normal BALB/c mouse spleen cells expressing surface immunoglobulin M. Examples were found of two types of nonproductive rearrangements, which may be responsible for allelic exclusion in normal B cells. In one of these rearrangements, a germ line D gene segment has joined to the JH4 gene segment but no V/D joining has occurred. We present evidence that D gene segments lie as a cluster between V and J gene segments in the germ line. A comparison of conserved sequences in V and D gene segments suggests that the D gene segments, which are found only in the heavy-chain gene family, may have evolved from V gene segments similar to the Vk family.     

Paleo-Immunology: Evidence Consistent with Insertion of a Primordial Herpes Virus-Like Element in the Origins of Acquired Immunity

Background

The RAG encoded proteins, RAG-1 and RAG-2 regulate site-specific recombination events in somatic immune B- and T-lymphocytes to generate the acquired immune repertoire. Catalytic activities of the RAG proteins are related to the recombinase functions of a pre-existing mobile DNA element in the DDE recombinase/RNAse H family, sometimes termed the “RAG transposon”.

Methodology/Principal Findings

Novel to this work is the suggestion that the DDE recombinase responsible for the origins of acquired immunity was encoded by a primordial herpes virus, rather than a “RAG transposon.” A subsequent “arms race” between immunity to herpes infection and the immune system obscured primary amino acid similarities between herpes and immune system proteins but preserved regulatory, structural and functional similarities between the respective recombinase proteins. In support of this hypothesis, evidence is reviewed from previous published data that a modern herpes virus protein family with properties of a viral recombinase is co-regulated with both RAG-1 and RAG-2 by closely linked cis-acting co-regulatory sequences. Structural and functional similarity is also reviewed between the putative herpes recombinase and both DDE site of the RAG-1 protein and another DDE/RNAse H family nuclease, the Argonaute protein component of RISC (RNA induced silencing complex).

Conclusions/Significance

A “co-regulatory” model of the origins of V(D)J recombination and the acquired immune system can account for the observed linked genomic structure of RAG-1 and RAG-2 in non-vertebrate organisms such as the sea urchin that lack an acquired immune system and V(D)J recombination. Initially the regulated expression of a viral recombinase in immune cells may have been positively selected by its ability to stimulate innate immunity to herpes virus infection rather than V(D)J recombination Unlike the “RAG-transposon” hypothesis, the proposed model can be readily tested by comparative functional analysis of herpes virus replication and V(D)J recombination.